Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

I need to do the following operation many times:

  1. Take two integers a, b
  2. Compute a * b mod p, where p = 1000000007 and a, b are of the same order of magnitude as p

My gut feeling is the naive

result = a * b
result %= p

is inefficient. Can I optimise multiplication modulo p much like exponentiation modulo p is optimised with pow(a, b, p)?

share|improve this question
Well, one simple optimization would be to combine all that into a single statement... it's about 6% faster in my tests. – kindall Jan 25 '12 at 19:51
Googling "fast modular multiplication" yields a number of papers, such as this one. – unutbu Jan 25 '12 at 20:04
9 digits might be too small for special algorithms such as Montgomery reduction yield any benefit. Don't optimize prematurely. What is the source for a,b (data-structure)? What does your profiler say? – J.F. Sebastian Jan 25 '12 at 20:18
"I have a feeling... is inefficient." Based on what? Have you tried it? What time constraints are you under? What's your overall algorithm? – S.Lott Jan 25 '12 at 20:42
If p = 1000000007 is fixed, then it seems likely speed could be improved by handcoding a little assembly language. Of course that would be CPU instruction set dependent, which the python tag dissuades me from elaborating as an answer. – hardmath Jan 27 '12 at 16:20

5 Answers 5

up vote 5 down vote accepted

To do this calculation in assembly, but have it callable from Python, I'd try inline assembly from a Python module written in C. Both GCC and MSVC compilers feature inline assembly, only with differing syntax.

Note that our modulus p = 1000000007 just fits into 30-bits. The result desired (a*b)%p can be computed in Intel 80x86 registers given some weak restrictions on a,b not being much bigger than p.

Restrictions on size of a,b

(1) a,b are 32-bit unsigned integers

(2) a*b is less than p << 32, i.e. p times 2^32

In particular if a,b are each less than 2*p, overflow will be avoided. Given (1), it also suffices that either one of them is less than p.

The Intel 80x86 instruction MUL can multiply two 32-bit unsigned integers and store the 64-bit result in accumulator register pair EDX:EAX. Some details and quirks of MUL are discussed in Section 10.2.1 of this helpful summary.

The instruction DIV can then divide this 64-bit result by a 32-bit constant (the modulus p), storing the quotient in EAX and the remainder in EDX. See Section 10.2.2 of the last link. The result we want is that remainder.

It is this division instruction DIV that entails a risk of overflow, should the 64-bit product in numerator EDX:EAX give a quotient larger than 32-bits by failing to satisfy (2) above.

I'm working on a code snippet in C/inline assembly for "proof of concept". However the maximum benefit in speed will depend on batching up arrays of data a,b to process, amortizing the overhead of function calls, etc. in Python (if that is the target platform).

share|improve this answer
Thanks. @BlueRaja-DannyPflughoeft. But I mistakenly threw an extra zero into my value for p. The version in the Question posted (8 zeros between 1 and 7) only needs 30 bits. I checked and the version with 9 zeros between 1 and 7 isn't prime (divisible by 23), I'll make the correction when I next post my code snippet. – hardmath Jan 30 '12 at 15:34

You mention that "a, b are of the same order of magnitude as p." Often in cryptography this means that a,b are large numbers near p, but strictly less-than p.

If this is the case, then you could use the simple identity

a-p \equiv a \pmod{p}

to turn your calculation into

result = ((a-p)*(b-p))%p

You've then turned one large multiplication into two large subtractions and a small multiplication. You'll have to profile to see which is faster.

share|improve this answer
If you can keep all your results in the machine-native integers rather than requiring promotion to Python's arbitrary-precision integers (which happens seamlessly when the values are big enough to require them), you can save a lot of time. This looks like a good way to do that. (Of course, as the answer says, you should do your own testing to see if it's actually faster.) – John Y Jan 28 '12 at 0:02
Timing it, this takes twice the time. – jterrace Jan 28 '12 at 0:04
As long as a, b and p are all 32bit integers (as in OP), I don't think this is going to help. – Thomas Ahle Feb 3 '12 at 1:28

This doesn't answer the question directly, but I would recommend not doing this in pure Python if you're looking for performance. Some options:

  • Make a small library in C that does your computations, and use Python's ctypes to talk to it.
  • Use numpy; probably the best option if you want to stay out of having to deal with compiling stuff yourself. Doing operations one at a time won't be faster than Python's own operators, but if you can put multiple ones in a numpy array, computations on them will be much faster than the equivalent in Python.
  • Use cython to declare your variables as C integers; again, same as numpy, you will benefit from this the most if you do it in batches (because then you can also optimize the loop).
share|improve this answer
+1 there is a fast algorithm, but implementing it in python is not likely to be any faster than (a*b) % p. – phkahler Jan 30 '12 at 16:34

Although this is trivally simple, you could try it and save some time on the mod p step by building a list of products based on 1000000007 (the size of the list depends on the size of a and b). Test for modulo on each of those (starting with the highest). Granted, this only helps if a & b >= sqrt(p) * 2.

share|improve this answer
Heh, this is probably where I cut-and-pasted the extra zero in my value of p! See BlueRaja-DannyPflughoeft's comment to me & my reply. – hardmath Jan 30 '12 at 15:44
@hardmath you certainly did...I was on my phone at the time, on a bus. It was bumpy. Counting zeros is hard. Apologies! – Droogans Jan 30 '12 at 15:50

There may be a clue to the optimization if you clarified what you mean by many times, for example if you were collecting the results from a high frequency loop, the loop may offer the means to optimize your routine.

Say the unoptimized loop was:

p = 1000000007
b = 123456789
a = 0
while a < p:
    result = (a * b) % p
    dosomething(a, b, result)
    a += 1

you could optimise out the * and % from the high frequency loop:

p = 1000000007
b = 123456789
a = 0
result = (a * b) % p
while a < p:
    dosomething(a, b, result)
    a += 1
    result += b
    if result >= p:
        result -= p
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.